Intracellular organization of bacteriophage T7 DNA: analysis of parenteral bacteriophage T7 DNA-membrane and DNA-protein complexes

Characterization of morphogenetic intermediates and progeny of normal and alkylated bacteriophage T7

Analysis of thin sections of Escherichia coli B cells infected by normal (nonalkylated) or alkylated bacteriophage T7 showed that alkylation altered phage morphogenesis. To understand these morphogenetic alterations, we have isolated phage-related particles from infected-cell lysates by differential and sucrose gradient centrifugation. Cells infected by normal and by alkylated phage produced mature phage particles, empty heads, and proheads; however, production of proheads and mature phage particles was less in the case of alkylated phage. These lysates also contained sedimentable material which migrated more slowly than empty heads on sucrose gradients. In the case of alkylated phage, this peak contained radioactive material in amounts nearly equal to that in either proheads or empty heads; for normal phage, this peak represented a smaller fraction of the total radioactivity. Examination of the gradient fractions by electron microscopy revealed appreciable quantities of phage tails and tail-related particles. The same gradient fractions contained phage tail proteins: gene products (gps) 11, 12, and 17 as well as smaller amounts of gp 8, the head-tail connector. In addition, these fractions contained two other proteins which we believe to be of bacterial origin. These proteins may be related to tail formation or function as part of the phage receptor. On the basis of our data, we propose an alternative morphogenetic pathway for T7 tail formation, a pathway which would involve formation of a complex of tail proteins prior to association with the phage head.

Characterization of the defects in bacteriophage T7 DNA synthesis during growth in the Escherichia coli mutant tsnB

The Escherichia coli mutant tsnB (M. Chamberlin, J. Virol. 14:509-516, 1974) is unable to support the growth of bacteriophage T7, although all classes of phage proteins are produced and the host is killed by the infection. During growth in this mutant host, the rate of phage DNA synthesis is reduced and the DNA is not packaged into stable, phagelike particles. The replicating DNA forms concatemers but the very large replicative intermediates (approximately 440S) identified by Paetkau et al. (J. Virol. 22:130-141, 1977) are not detected in T7+-infected tsnB cells. These large structures are formed in tsnB cells infected with a T7 gene 3 (endonuclease) mutant, where normal processing of the large intermediates into shorter concatemers is blocked. At later times during infection of tsnB cells, the replicating DNA accumulates in molecules about 30% shorter than unit length. Analysis of this DNA with a restriction endonuclease indicates that it is missing sequences from the ends (particularly the left end) of the genome. The loss of these specific sequences does not occur during infections with T7 gene 10 (head protein) or gene 19 (maturation protein) mutants. This suggests that the processing of concatemers into unit-length DNA molecules may occur normally in T7 -infected tsnB cells and that the shortened DNA arises from exonucleolytic degradation of the mature DNA molecules. These results are discussed in relation to our recent observation (M. A. DeWyngaert and D. C. Hinkle, J. Biol. Chem. 254:11247-11253, 1979) that E. coli tsnB produces an altered RNA polymerase which is resistance to inhibition by the T7 gene 2 protein.

Regulation of transcription of the late genes of bacteriophage T7

The transcription program of bacteriophage T7 in vivo was analyzed by hybridizing T7 mRNAs, labeled at intervals after infection, to Hpa I restriction fragments of T7 DNA. Transcripcion of the late genes is temporally regulated: class II genes are transcribed between 4 and 16 min after infection; most class III genes are transcribed from 8 min after infection until lysis. Genes 8--10 are transcribed as both class II and class III genes. The rate of T7 RNA synthesis decreases sharply at 10 min after infection. The rapid decrease in the rate of T7 RNA synthesis and the shutoff of class II RNA synthesis were not observed in cells infected with phage defective in gene 3.5 (lysozyme). Although the decrease in the rate of T7 RNA synthesis is independent of DNA replication, the failure to shut off class II RNA synthesis normally in 3.5-- -infected cells may reflect the role of T7 lysozyme in DNA replication. In vitro, the regions of T7 DNA transcribed by the phage RNA polymerase were found to be dependent upon ionic conditions.